Big Bang vs Black Hole: Exploring the Universe's Past

In summary, the conversation discusses the concept of a singularity in the universe and how it relates to black holes. The origin of the term "singularity" is explained and it is noted that there is no proof of singularities occurring in nature. The question of why the entire universe did not become a black hole at the time of the Big Bang is raised and it is explained that the expansion of space plays a role in preventing this from happening. The idea of the universe being very small at the beginning of expansion is also addressed. Different models for the early stages of the universe are mentioned, including lambdaCDM, but it is acknowledged that there is still much unknown about the physics involved.
  • #1
gregtomko
71
0
If the universe was at or near a singularity in the past, why is it not a black hole now? How can part of the universe become a black hole, and not the whole universe?
 
Last edited:
Space news on Phys.org
  • #2
gregtomko said:
If the universe was at or near a singularity in the past, why is it not a black hole now? How can part of the universe become a black hole, and not the whole universe?

Could you be a bit clearer. We have no proof that singularities occur in Nature. The original meaning of the term is a breakdown in some man-made theory. A place where the theory blows up and fails to match physical reality. So what is or is not a "singularity" depends totally on which man-made physical theory you happen to be using.

Your questions don't seem to make sense. It sounds like you are imagining something as real, that according to mainstream cosmology is not real--but what is it exactly?

Why would you suppose that the whole universe would become a black hole? As far as we know, from the standard model of cosmology, it is on track to continue expanding. Why should it collapse? You could be more explicit in describing what you are imagining.

Here's a good place to get started understanding cosmology:
http://www.mso.anu.edu.au/~charley/papers/LineweaverDavisSciAm.pdf
The first page is blank, so scroll down.
It still uses words like "singularity" a bit confusingly, but it's good for starters.

I guess a friendly word of advice would be to be cautious about believing TV and mass market popularization of cosmology.
 
Last edited:
  • #3
marcus said:
Your questions don't seem to make sense.
The "big bang" as far as I understand, refers to a time when the universe was very small. It then expanded. When there is a high enough concentration of mass in our universe now, it becomes a black hole. Why is it that when all the mass was concentrated at or around the "big bang" did it not just become a black hole?
 
Last edited:
  • #4
The BB didn't happen as a singularity as per a black hole.
Rather its a rapid expansion of spacetime. The BB model only describes from 10 to the -44 seconds forward.
(sorry for the longhand typing from phone)

This era is the planch epoch.
I can provides listing of epochs for you if you wish.
During the planch epoch, matter did not exist. Instead its best to describe this epoch in terms of planch length, planch time and units of planch time.
There are a couple of models that represent how this works.
The one with the best fit to data is lamdaCDM.
However there is a few models that are valid as to how this all works from before Planch era.
One is through what is the false vacuum method described by A. Guth which can easily described as false vaccuum. This model describes everything starting from nothing. Lawrence R Kraus supports a later variation of this model.
I'll let others explain Loop quantum gravity.
Hope that helps
 
Last edited:
  • #5
I didn't see Mordred already replied. Had to do a chore and got sidetracked half way thru. I'll leave this as it is anyway.
gregtomko said:
The "big bang" as far as I understand, refers to a time when the universe was very small. ...
Well the term "big bang" is misleading because it suggests an explosion from a point outwards into empty space. That is not the idea. "start of expansion" is more neutral.

In the standard picture of the early stage of expansion all space was filled with a uniform high density. There was no empty space and there was no one favored location where stuff was concentrated. We don't know 'very small' but we do think "very dense".

High density does not by itself cause collapse to a black hole.
There is a kind of "tug-of-war" contest between the expansion rate and the density.
In popularizations they don't tell you about that. They only tell you that IN NON-EXPANDING SPACE a certain density concentrated at some location will result in formation of a black hole at that location. They don't discuss other cases.

Suppose the expansion rate overwhelms the density.

We have no proof that the universe as a whole was "very small" at the start of expansion. According to the mainstream expansion cosmology model it could have been infinite volume, or a large finite volume at the start. Measurements are not yet good enough to put a number on the current volume of the universe as a whole. We only know the size of the currently observable part of it.

The main thing is that it was very DENSE. So the currently observable portion would have been concentrated in a very small volume. What we can currently see, out of the limits of observation, was very small at the start.

What started the expansion is so far not known. There are various theories.
 
Last edited:
  • #6
Mordred said:
There are a couple of models that represent how this works.
The one with the best fit to data is lamdaCDM.

So you are saying that space was expanding so fast after the big bang, that a black hole was impossible?
 
  • #7
marcus said:
High density does not by itself cause collapse to a black hole.
There is a kind of "tug-of-war" contest between the expansion rate and the density.

Thanks!
 
  • #8
We don't know the physics involved under conditions approaching those of the BB model. We only know they are different.
 
  • #9
It sounds a little funny that at the beginning, expansion was super fast. Then during most of forever, expansion was close to linear; and just now expansion is speeding up again. I know that’s what the models say, but it seems like a pibtac
 
Last edited:
  • #10
gregtomko said:
It sounds a little funny that at the beginning, expansion was super fast. Then during most of forever, expansion was close to linear; and just now expansion is speeding up again. I know that’s what the models say, but it seems like a pibtac

The reason for this has everything to do with the sequence of events that occurred during the initial stages. Prior to the planch epoch opinions differ on what occured.
Here is a list of some of the earlier stages.
http://www.uni.edu/morgans/astro/course/Notes/section3/bigbang.html

In the early universe radiation was dominated so inflation was rapid. Later matter formed after the temperature dropped below 3000 kelvin. Big bang nucleosynthesis best describes this sequence.
that matter slowed expansion so its referred to as the matter dominated era. However dark energy (cosmological constant/vacuum energy) continued growing. Eventually in non gravitational bound regions. Ie the voids between galaxy clusters. The energy driving expansion is currently explained as vacuum energy. This energy became strong enough to start accelerating expansion. Leading to what we see today in the lambda dominated universe
 
Last edited:
  • #11
Mordred said:
In the early universe radiation was dominated so inflation was rapid.
Just to clarify, inflation occurs during inflaton (or vacuum energy) domination, not radiation domination. Radiation domination occurs after inflation when the inflaton decays.

gregtomko, the models are what they are because that's what the data tells us. As others have said, we don't have a physical model for what, if anything, occurred at t=0. The "big bang" is the name given to the model describing the evolution of the early universe as it expanded from a hot, dense initial phase to an older universe. We can apply this model all the way back to very early times, as Mordred points out, we just can't apply it beyond the Planck scale. What was there? Nobody knows. The singularity that arises from GR does not indicate anything physical, it merely signals that the theory is being applied outside its bounds. So we'd be remiss to take the singularity seriously. In any event, it's certainly true that densities were very high back then. So does this imply that a black hole should have formed? Black holes arise when a spherically symmetric mass distribution becomes sufficiently dense. Was the mass density of the early universe spherically symmetric? No! (at least not from the time that the big bang is a descriptive model of the universe) The early universe was homogeneous and isotropic, and the gravity of such a mass distribution causes the universe to expand (quickly or otherwise, it can even contract!). But it does not form a black hole -- it doesn't have the correct symmetry. It turns out that gravitation cares very much about the nature of the mass/energy doing the gravitating.
 
  • #12
The problem I think is in what we call usually a "singularity"... a Black Hole singularity is not necessarily the same thing as the Big Bang singularity.
Black Hole singularity is a local space-time singularity and is covered by an event horizon.
In the case of Big Bang instead the singularity is non-local, is extended to the whole space-time; moreover the only horizon emerging from this picture is a particle horizon, not an event horizon.

The inevitability of singularities was proved in two really important theorems by Roger Penrose (a collapsing star with a mass greater than a certain limit will necessarily end up in a singularity) and by Stephen Hawking (this one indeed regards the Big Bang singularity, even if I do not know in detail what aspects of this singularity). The way used to prove these theorems is to study geodesic incompleteness, meaning that if we show that a geodesic of space-time cannot be extended to ##+\infty## and ##-\infty## in the affine parameter space, then it will end up in a singularity (future-incompleteness for BHs, past-incompleteness for BB).

These results anyway are summarized in the book by Hawking & Ellis "The large scale structure of space-time" (Cambridge university press) but it is really technical and difficult to read, so I would advise to read only having a good knowledge of differential geometry and General Relativity.
 
  • #13
OK so, initially the universe was very dense, and not neccessarily a singularity. But doesn't the common origin of particles/spacetime imply some sort of singularity in the beginning?
 
  • #14
jety89 said:
But doesn't the common origin of particles/spacetime imply some sort of singularity in the beginning?

Yes, there IS a singularity in the beginning. And you can't talk of common origin of particles and space-time... as far as we know particles (at least as we know them) formed later in the evolution... even quarks formed later. In the Big Bang we do not know anything of what happened in term of physical processes. At those energies (remember that diverging mass density implies diverging energy as well) also Quantum Field Theory fails and we will have to use Quantum Gravity. Problem is we do not have a theory for that still, only some candidates. Good candidates are String Theory, Loop Quantum Gravity and all that stuff, but they are not so developed to be able to explain all this, at least for now.
 
  • #15
jety89 said:
OK so, initially the universe was very dense, and not neccessarily a singularity. But doesn't the common origin of particles/spacetime imply some sort of singularity in the beginning?

To emphasize what tia89 did not make completely explicit, what he is describing (" ... we do not know anything of what happened" ...) IS what we mean by singularity. A black hole singularity and a big bang singularity do not necessarily have ANYTHING to do with each other beyond the fact that we call them the same thing. It would be a LOT more clear if no one every used the term "singularity" but always said "a place where our theories break down and we have no idea what was going on"; that's what "singularity" is short-hand for, but the fact that different kinds of singularities have the same name leads to the false conclusion that they may be related. (They MAY be related, but we don't know that and they probably aren't).
 
  • #16
Well, theories aside, I think it still makes sense to talk about a common origin, considering the *unchallenged* uniformity of nature: an electron is just like any other electron, anywhere, as far as anyone can tell, so we know the universe had to have a single/singular origin, we just don't have any conceivable idea how it happened beyond the Planck epoch. And, as I understand from the comments above, it needed not to be infinitesimally small at that point. So just how small would have been, say, the currently observable part of the universe in the Planck epoch? Or the universe as a whole?
 
  • #17
jety89 said:
Well, theories aside, I think it still makes sense to talk about a common origin ...

A common origin for WHAT? The universe and black holes? I don't think so.

... just how small would have been, say, the currently observable part of the universe in the Planck epoch?
I've heard things from the size of an atom to the size of a grapefruit. Folks seems to just make stuff up. BUT ... VERY small compared to the 95+billion light years across that it is now!

... Or the universe as a whole?

Totally unknown, could be infinite. If it's infinite now, it was infinite then (finite things don't become infinite).
 
  • #18
jety89 said:
Well, theories aside, I think it still makes sense to talk about a common origin, considering the *unchallenged* uniformity of nature: an electron is just like any other electron, anywhere, as far as anyone can tell, so we know the universe had to have a single/singular origin, we just don't have any conceivable idea how it happened beyond the Planck epoch. And, as I understand from the comments above, it needed not to be infinitesimally small at that point. So just how small would have been, say, the currently observable part of the universe in the Planck epoch? Or the universe as a whole?

And here you come again in the realm of theories, which by the way can't be put aside as you would like to do... and this because we do not have any idea of what really happened. There are only theories and sometimes they don't even agree.
Anyway as for the question about the size of the universe, it all depends on inflation (again a theory) http://en.wikipedia.org/wiki/Inflation_(cosmology [Broken]). And I do not think there is a way (at least by now) to answer your question, as we can not observe anything beyond the Hubble horizon (you can visualize it as a sphere around us with the radius given by the time passed from Big Bang till today).
And again, aside knowing that the Big Bang is the most probable "beginning" of the Universe (also here there are theories which avoid the Big Bang, but they are not in agreement with observations most of times), what is actually Big Bang is unknown, and will probably be unknown for many years... giving a size to the Universe is then clearly impossible, at least to my knowledge.
 
Last edited by a moderator:
  • #19
phinds said:
A common origin for WHAT? The universe and black holes? I don't think so.

I wasn't implying a similarity between a black hole singularity and the singularity "at the beginning".

@tia89
I think what we can know about the BB, is that it was the singular origin of the universe.

The fact that, for example, photons coming from opposite ends of the observable universe report about a remarkably self-similar universe, talks about that in the past, the predeccessors of those parts of the universe were not simply closer to each other, but were, in fact, the results of the same process, that, as it seems now, happened prior to the Planck era. You could call that a singular origin of the universe.
Now, a singular origin implies finiteness, so I think the universe we live in is finite, although very-very big.
 
  • #20
jety89 said:
The fact that, for example, photons coming from opposite ends of the observable universe report about a remarkably self-similar universe, talks about that in the past, the predeccessors of those parts of the universe were not simply closer to each other, but were, in fact, the results of the same process, that, as it seems now, happened prior to the Planck era. You could call that a singular origin of the universe.
Now, a singular origin implies finiteness, so I think the universe we live in is finite, although very-very big.
This is shear speculation. Your assertion that all things emerged from the same singular origin because they are similar is but one possible conclusion. First, as has been painstakingly laid out in this thread -- the big bang singularity is not physical. You can imagine that there was a singularity in the past, and you can call this thing the big bang, but you wouldn't be doing science then. You'd do just as well to call it God.

The uniformity of the CMB to which you refer does not imply a singular origin -- what would that even mean? Again -- we don't have any physical model whatsoever that is operative at the times about which you are speculating, let alone one that describes a physical singularity in any meaningful way. What the uniformity of the CMB tells us is that very early on (after the Planck time, btw), the process that governed the generation of the CMB photons varied little across space. This requires really 2 things: that the laws of physics are the same across the observable universe and that the conditions (the inputs to these laws) were similar across the universe. The former is generally assumed, the latter can be understood by proposing an inflationary epoch, for example.

You also argue that the fact that electrons are identical implies that the universe had a singular beginning, i.e. all electrons came from the same place. But what about those electrons that we create in colliders every day? Or those that result from pair production following high energy cosmic ray collisions in the upper atmosphere? It makes more sense to suppose that it's the laws of physics that are prescribed and uniform -- not that all matter with similar properties necessarily came from the (exact) same (singular) point.
 
  • #21
jety89 said:
I think what we can know about the BB, is that it was the singular origin of the universe.

Which is saying all and nothing...

jety89 said:
The fact that, for example, photons coming from opposite ends of the observable universe report about a remarkably self-similar universe, talks about that in the past, the predeccessors of those parts of the universe were not simply closer to each other, but were, in fact, the results of the same process, that, as it seems now, happened prior to the Planck era.

This is exactly the fact to explain which inflation was introduced... and (as also bapowell pointed out) it happened AFTER the Planck era... about which we do not know anything.

jety89 said:
You could call that a singular origin of the universe. Now, a singular origin implies finiteness, so I think the universe we live in is finite, although very-very big.

I also DO call that the singular origin of the Universe (read my other posts). But there are interpretations claiming that the Big Bang is a simultaneous "explosion" happening in all the points of an infinite space-time rather than an "explosion" from a localized "single point". But this is all philosophy, not physics, and no one is right or wrong... we simply do NOT know.
 
  • #22
tia89 said:
I also DO call that the singular origin of the Universe (read my other posts). But there are interpretations claiming that the Big Bang is a simultaneous "explosion" happening in all the points of an infinite space-time rather than an "explosion" from a localized "single point". But this is all philosophy, not physics, and no one is right or wrong... we simply do NOT know.
Nobody doing serious science refers to the big bang as an "explosion". And it is *not* merely philosophy to discuss the nature of the early moments of the expansion -- we have actual data on these points! Observations of the cosmos reveal a uniform, isotropic expansion of space: this is supportive of the notion that even back to the earliest times, expansion was occurring uniformly throughout space and was not localized. So while for sure we don't know the mechanism that started the expansion, we have a pretty good idea that it was not a localized event.
 
  • #23
I might be phrasing misconceptions, and then it is appropriate to strike them down.

I think that what I was challenging here, is the notion that there are no clues as to what happened before the Planck era(or the inflation, thereof). Perhaps it is more appropriate, then, to talk about the reality of physical laws. As I understand it, the laws of physics are, as far as we can tell, the same across all of the observable universe, and operate independently in far away regions of spacetime. This implies that there are multiple 'copies' of these laws.

During the Planck epoch, as I understand from the previous comments, all that existed, was a very dense sea of "something". So what can we tell with some level of certainty about that "something" that made up this "soup"?
 
  • #24
bapowell said:
And it is *not* merely philosophy to discuss the nature of the early moments of the expansion -- we have actual data on these points!

My apologies... I meant it is philosophy to talk about what happened THE VERY MOMENT of Big Bang... I am perfectly aware that we have data about the early moments of expansion
 
  • #25
jety89 said:
During the Planck epoch, as I understand from the previous comments, all that existed, was a very dense sea of "something". So what can we tell with some level of certainty about that "something" that made up this "soup"?

That is exactly the point... we have a lot of theories but no sure knowledge of this... as you will know, at those energies gravity becomes (perhaps?) coupled to the other 3 fundamental interactions... but still there is not a clear theory for Quantum Gravity, only possible candidates (main ones being Loop Quantum Gravity and String Theory)... no certainty then
 
  • #26
During the Planck epoch, as I understand from the previous comments, all that existed, was a very dense sea of "something". So what can we tell with some level of certainty about that "something" that made up this "soup"?
During the Planck epoch, we don't know what particles (or more generally "degrees of freedom") are relevant. We do, however, generically expect that there will be quantum mechanical manifestations of gravity that will govern the dynamics in some way -- we need a complete quantum theory of gravity in order to understand the specifics, but much progress has been and we are beginning to get a sense of the broad features of this era. Unfortunately, the particle spectrum is still uncertain and likely depends on the details of this as-yet unknown theory.

That said, as the universe emerged from the Planck time, one expects to see a particle spectrum given by the appropriate particle physics model at the relevant energies. This too is not fully known, but we have a much better picture of what it looks like. For example, if supersymmetry turns out to be a good symmetry of nature, then we expect to see a whole swarm supersymmetric particles in existence along with those from the standard model. As long as the temperatures are high enough, the general rule is that all particles with energies below this temperature can exist.

Inflation happens after the Planck time, and we have a pretty good handle on how it works and what kinds of universe it gives us. Observations of the CMB and large scale structure surveys have imposed some constraints on the physics of inflation, but there's much we still don't know (stay tuned for the ESA Planck surveyor press release in late March for an update!). In order for inflation to get started, there needs to be a sufficiently high density of a certain type of matter in the universe. This matter is unusual in that it has the properties of the vacuum, but it's dynamical in the sense that its energy density changes as the universe expands. Regions in which we find this sufficiently high concentration of vacuum-like matter undergo inflation. So, the challenge is to put a finger on the agent of the inflation -- to find a particle that comes from fundamental particle theory that has the properties of the strange matter needed to drive inflation. It's generically dubbed the "inflaton", but we're still hunting for it.
 
  • #27
Great! Thanks!
 
  • #28
I've been reading (and asking) about the recent pop science articles on the Higgs mass and the vacuume instability (metastable). If this turns out to accurately describe the universe, does it in some way predict the past as well?

To be specific, in my mind the logical extension of the vacuume instability is that there was an even less stable vacuume in the past and our universe is moving outward annihilating the space in the older universe and at the same time leaving what appears to be a big bang at the edge of the expanding bubble.

This would also imply that most likely the previous spacetime with an even less stable vacuume is out there well beyond the observable universe.

Are there any articles or calculations where our "universe" bubbles out of the vacuume instability of the previous?
 
  • #29
See chaotic inflation and eternal inflation.
 

1. What is the Big Bang theory?

The Big Bang theory is a scientific model that explains the origin and evolution of the universe. It states that the universe began as a singularity, a point of infinite density and temperature, and has been expanding and cooling ever since.

2. What is a black hole?

A black hole is a region of space with a gravitational pull so strong that nothing, including light, can escape from it. It is formed when a massive star collapses under its own gravity.

3. How do the Big Bang and black holes relate to each other?

The Big Bang theory explains the beginning of the universe, while black holes are a result of the universe's evolution. Black holes can grow in size and mass over time, and are thought to play a key role in the formation of galaxies.

4. Can we observe the Big Bang and black holes?

No, we cannot observe the Big Bang directly as it occurred about 13.8 billion years ago. However, we can observe the cosmic microwave background radiation, which is considered the leftover energy from the Big Bang. We can also indirectly observe black holes through their effects on surrounding matter and light.

5. Which theory is more widely accepted - the Big Bang or black holes?

The Big Bang theory is more widely accepted by the scientific community as it has more evidence and observations supporting it. However, the existence of black holes is also well-supported by evidence, including gravitational waves detected by LIGO. Both theories are important in understanding the history and workings of the universe.

Similar threads

Replies
7
Views
729
Replies
25
Views
2K
Replies
2
Views
746
Replies
22
Views
3K
Replies
6
Views
1K
  • Cosmology
Replies
13
Views
2K
Replies
49
Views
4K
  • Cosmology
Replies
11
Views
1K
  • Cosmology
Replies
20
Views
1K
Back
Top